Space Transportation and Dual Use of Aerospace
Technology Nikolaus A. Adams
Institute of Aerodynamics
Technische Universität München
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I believe that a scientist looking at nonscientific problems is just as dumb as
the next guy.Richard P. Feynman
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0. Content
1. The Need for Space Transportation
2. Current and Future Space Transportation Activities
3. Individual Risk of Space Transportation (Example)
4. State of Space Transportation Technology and Current Research
5. Dual-Use Potential of Space Transportation
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Mc Masters, 2006
0. Content
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Do we need space transportation?
This is an invalid question, requirements are:
1. We need to know the implications of space access.
2. We need to know whether we can obtain affordable space access.
Of much larger impact for the long-term development of societies are the side effects of space technology: education, access to top-technology, ability to handle very complex technical systems, advanced materials.
These spin-off effects are very hard to estimate. One can proceed only based on the general experience that the leading technological societies perform space travel (the causal connection is not proven).
Emerging industrial societies (Russia, China, India) believe in this causality (and we watch this with concern).
1. The Need for Space Transportation
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1. The Need for Space Transportation
Strategic Objectives of European Space Policy
• Develop and exploit space applications serving Europe’s public policy objectives and needs of European enterprises and citizens, including in the field of environment, development and global climate change.
• Meet Europe’s security and defence needs as regards space.
• A strong and competitive space industry which fosters innovation, growth and the development and delivery of sustainable and cost-effective services.
• Contribute to knowledge-based society (science and exploration).
• Unrestricted access to new and critical technologies, systems and capabilities.
Independent access to space is an inevitable requirement for societies which rely on industrial revenue.
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1. The Need for Space Transportation
Highlights of Space Exploitation
• Navigation, Positioning
• Telecommunication
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1. The Need for Space Transportation
• Weather Prediction
• Geological Surveillance
• Environmental Monitoring
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1. The Need for Space Transportation
• Unmanned-launch capabilites:
− World revenue in satellite technology (2007) 123 Billion US$
− Payload < 1,500 kg into low earth orbit or polar orbit (small observation satellites)
− Payload < 3,000 kg into geostationary transfer orbit (communication satellites, weather satellites)
− Payload < 10,000 kg into geostationary transfer orbit (weather satellites, large communication satellites)
− Payload > 10,000 kg into low earth orbit (ATV service for ISS, Hubble space telescope)
• Manned-launch capabilities:
− Payload < 25,000 kg into low-earth orbit (manned missions to ISS)
− Payload < 20,0000 kg into low-earth orbit (manned missions to moon)
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2. Current and Future Space Transportation Activities
• Current unmanned-launch capabilites:
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2. Current and Future Space Transportation Activities
• Current manned-launch capabilites:
Don't tell me that man doesn't belong out there. Man belongs wherever he wants to go - and he'll do plenty well when he gets there.
Wernher von Braun, 1958
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2. Current and Future Space Transportation Activities
• Future manned-launch capabilites:
Europe:Ariane 5 + ATV evolution
US:Ares I-V + CEV
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3. Individual Risk of Space Transportation (Example)
Opfer müssen gebracht werden. Tombstone inscription of Otto Lilienthal.
– Film 1 –
Please click on the seperate button!
3. Individual Risk of Space Transportation (Example)
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3. Individual Risk of Space Transportation (Example)
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4. State of Space Technology and Current Research
On July 1, 2008, the German Research Foundation (Deutsche Forschungsgemeinschaft) decided to launch the Collaborative Research Center (Sonderforschungsbereich) TRR 40 at TU München, RWTH Aachen, TU Braunschweig and U Stuttgart with multi-million Euro funding for 4 years (with a possible extension to twelve years).
Astrium GmbH, industrial prime contractor in European Space Research, is an equal research partner providing significant additional funding.
The motivation is to maintain and extend research leadership in essential components of technologically extremely demanding components of future space transport systems.
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4. State of Space Technology and Current Research
– Film 2 –
Please click on the seperate button!
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1. Wissenschaftliche Zielsetzung – 1.1 Motivation
Data for Ariane 5 Vulcain 2 EPC main engine:
• Thrust 960-1350 kN• Combustion chamber pressure 115 bar• Fuel consumption 317 kg/s• Combustion chamber has 566 injectors, 468 cooling
channels• Cooling power density 100 MW/m2
• Interactions- nozzle flow ↔ exterior flow
- shock ↔ boundary layer, shock ↔ shock
• Heat transfer, radiation• Phase transition, combustion• Boundary-layer and combustion instabilities
• Sonic conditions at about 7 km altitude• Maximum aerodynamic load at about Ma=2• Stagnation pressure about 0.5 bar• Thermial load of the hull about 0.5 GW• Unsteady turbulent, transonic wake, buffeting
4. State of Space Technology and Current Research
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Quelle: Astrium
Combustion chamber of the Vulcain engine:
cooling channels
• Failure of Ariane 5 EPC-main-engine nozzle on December 11, 2002
• Nozzle redesign and Ariane 5 re-launch on February 12, 2005
• Required investments: 400 M€
• ESA investigation:
- Nozzle structure failure due to flight loads
- Under-designed cooling
- Insufficient prediction due to ground tests
- Insufficient numerical prediction
• Measures:
- Increase of cooling flow
- Additional thermal protection
- Additional reinforcements
1. Wissenschaftliche Zielsetzung – 1.1 Motivation4. State of Space Technology and Current Research
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• Current technologies are largely empirical and experimentally developed
• Prediction models are calibrated on the final design or product
• New technologies and optimization of existing technologies are beyond the available development and prediction potential.
Needs:
• Extend theoretical and fundamental knowledge.
• Understanding by modeling.
• Prediction by efficient and reliable simulation.
1. Wissenschaftliche Zielsetzung – 1.1 Motivation4. State of Space Technology and Current Research
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Break-through technologies for future space transport:
Efficiency ImprovementRobust Operation Re-usable
1. New nozzle concepts
4. Innovative methods for bluff-body wake flow control
3. Innovative cooling concepts
2. Alternative fuels and combustion concepts
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4. State of Space Technology and Current Research
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5. Dual-Use Potential of Space Transportation
Although some people think scientists make war, I find it easy to take the position that war makes scientists.
Theodore von Karman in “The Wind and Beyond”
Any high technology has dual-use potential (actually, also almost any low-technology, too).
Any space transportation system which reaches earth orbit can serve to deliver weapons.
Any observation satellite can gather civilian or military information.
Any communication satellite can transmit civilian or military messages.
Any navigation satellite can deliver civilian or military positioning.
Any defensive system can be used for supporting offensive operations.
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5. Dual-Use Potential of Space Transportation
Currently no space-based weapons (to public knowledge)—although USA declines an international treaty on that (probably with good reason).
Space technology used for reconnaissance and communication.
Ballistic rocket-based transport systems to deliver warheads are available even to low-technology societies.
Defence against such rockets requires highest-end technology, available currently only to USA (and possibly Israel), possible later solutions may require kinetic kill vehicles or lasers based in space (see above).
Kinetic anti-satellite weapons are available to USA, Russia and China.
Laser-based anti-satellite weapons (blindfolding) under development (known) by USA and China (alleged test against US satellite in 2006).
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5. Dual-Use Potential of Space Transportation
Proliferation is the main risk for safety of free societies.
Can proliferation be contained?
Selling of technology is impossible to contain.
Can development by potentially threatening societies be prohibited?
In the short term “yes,” in the long term “no.”
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5. Dual-Use Potential of Space Transportation
Famous counterexample:
Argument of Szilard’s July 17, 1945, petition (July 16 Trinitiy Shot) is essentially that by the USA’s decision not to employ nuclear weapons the deployment of nuclear weapons could be prevented, respectively a nuclear-arms race could be avoided, for the foreseeable future as no one will know about their real power. Keep in mind that the development cost of a single weapon was 2 Billion US$ (reference 1945, 2 % of gross domestic product, would correspond to about 300 Billion US$ today).
Ignores that fact that also science (and not only technology or goods) can be proliferated (as we know now).
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5. Dual-Use Potential of Space Transportation
What can or should the individual scientist do?
Science!
As a note in passing:
More recent accounts of Heisenberg’s role in the Nazi war machine indicate that it is likely that he in fact obstructed the decision-makers (Speer) from realizing the potential of nuclear research in terms of weaponry.
That gives rise to the ironic situation that Heisenberg was blamed by his former colleagues for cooperating with the Nazi government, whereas it rather appears that he prevented the necessary investments into nuclear bomb technology while his colleagues actively pursued its development.
Thomas Powers (Heisenberg’s war, 1993) contradicts David Cassidy (Uncertainty, 1992) and Michael Frayn (Kopenhagen), and the conclusions of Jeremy Bernstein (Hitler’s Uranium Club: The Secret Recordings at Farm Hall, 1992).